METHOD AND DEVICE FOR EFFICIENTLY USING IPv4 PUBLIC ADDRESS

ABSTRACT

A method and device for efficiently using IPv4 public addresses applied to a core translator deployed between an IPv4 Internet and an IPv6 network, which maps an IPv4 public address into a first-type IPv6 address having a first-type prefix according to a transport layer protocol port range used by an IPv6 server in the IPv6 network, so that the IPv6 server uses the first-type IPv6 address to communicate with a client in the IPv4 Internet; and maps the IPv4 public address into a second-type IPv6 address having a second-type prefix according to a transport layer protocol port range used by an client in the IPv6 network, so that the client in the IPv6 network uses the second-type IPv6 address to communicate with a IPv4 server in the IPv4 Internet. The IPv6 server and the client in the IPv6 network can use the same IPv4 public address to provide different services.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to Chinese Patent Application No.201810196537.8 filed on Mar. 9, 2018, the entirety of which isincorporated by this reference.

TECHNICAL FIELD

The embodiments of the present application relate to the technical fieldof computer network communication, and specifically to a method anddevice for efficiently using IPv4 public address.

BACKGROUND

IPv4 protocol has achieved great success with the rapid development ofthe Internet over the past 20 years. At present, there are more than 3billion IPv4 users worldwide, accounting for more than 50% of the totalpopulation. However, the rapid growth of the network scale alsohighlights a series of serious problems of IPv4, including insufficientaddress space, routing scalability issues and etc. IPv6 protocol is anInternet protocol of the next generation, and used to replace IPv4. IPv6has characteristics such as huge address space (2{circumflex over( )}128), hierarchical addressing and routing mechanisms, betterend-to-end features, better security and mobility support.

However, IPv6 is not compatible with IPv4. In order to interconnect anewly-built IPv6 network with the IPv4 Internet, the standards proposedby the IETF include stateless translation scheme IVI, statefultranslation scheme NAT64, stateless dual-translation technology MAP-Tand stateful dual-translation technology 464xlat etc. It is worthpointing out that any technology that communicates with the IPv4Internet needs an IPv4 public address. Therefore, IPv4 public addressesare extremely scarce resources in the coexistence phase of IPv4 andIPv6. For a client, it is a mature technology to allocate IPv4 privateaddresses and reuse IPv4 public addresses with the transport layerports. But for servers, this technology cannot be used since a servermust use IPv4 public addresses and specify specific transport layerports. Therefore, each IPv4 public address can only have one specifictransport layer port (service port) and cannot be reused. The massiveuse of cloud computing urgently requires IPv4 public addresses of alarge number of user servers.

In view of this, how to allow IPv4 public addresses to be available toboth servers and clients in the IPv6 network so as to maximize the useof the scarce IPv4 public address resources, has become a technicalproblem to be solved at present.

SUMMARY

Since the problems above exist in the existing methods, the embodimentsof the present application provide a method and device for efficientlyusing IPv4 public address.

In one aspect, the embodiments of the present application provide amethod for efficiently using IPv4 public address, which is applied to acore translator deployed between an IPv4 Internet and an IPv6 network,including:

mapping an IPv4 public address into a first-type IPv6 address having afirst-type prefix according to a transport layer protocol port rangeused by an IPv6 server in the IPv6 network, so that the IPv6 server usesthe first-type IPv6 address to communicate with a client in the IPv4Internet;

mapping the IPv4 public address into a second-type IPv6 address having asecond-type prefix according to a transport layer protocol port rangeused by an client in the IPv6 network, so that the client in the IPv6network uses the second-type IPv6 address to communicate with a IPv4server in the IPv4 Internet.

Alternatively, before mapping the IPv4 public address into thefirst-type IPv6 address having the first-type prefix according to thetransport layer protocol port range used by the IPv6 server in the IPv6network, so that the IPv6 server uses the first-type IPv6 address tocommunicate with the client in the IPv4 Internet, the method furtherincludes:

configuring translation parameters including the first-type prefix usedby the IPv6 server in the IPv6 network, the second-type prefix used bythe client in the IPv6 network, a transport layer port range of the IPv6server, a transport layer port range of the client in the IPv6 network,an IPv4 public address pool, and an IPv4 private address pool with asame size of the IPv4 public address pool; wherein the IPv4 publicaddress pool and the IPv4 private address pool have a one-to-one mappingrelation.

Alternatively, the first-type prefix is not overlapped with thesecond-type prefix.

Alternatively, mapping the IPv4 public address into the first-type IPv6address having the first-type prefix according to the transport layerprotocol port range used by the IPv6 server in the IPv6 network, so thatthe IPv6 server uses the first-type IPv6 address to communicate with theclient in the IPv4 Internet includes:

determining whether a target port of an IPv4 message sent by the clientin the IPv4 Internet is within the transport layer port range of theIPv6 server in the IPv6 network, when receiving the IPv4 message sent bythe client in the IPv4 Internet;

translating the IPv4 message sent by the client in the IPv4 Internetinto an IPv6 message having the first-type prefix and sending the IPv6message to the IPv6 server, when the target port of the IPv4 messagesent by the client in the IPv4 Internet is within the transport layerport range of the IPv6 server in the IPv6 network;

translating the IPv6 message fed back by the IPv6 server into the IPv4message and sending the IPv4 message to the client in the IPv4 Internet,when receiving the IPv6 message fed back by the IPv6 server.

Alternatively, the IPv4 message sent by the client in the IPv4 Internetis sent based on a record A which is obtained by the client in the IPv4Internet querying DNS through a domain name server.

Alternatively, mapping the IPv4 public address into the second-type IPv6address having the second-type prefix according to the transport layerprotocol port range used by the client in the IPv6 network, so that theclient in the IPv6 network uses the second-type IPv6 address tocommunicate with the IPv4 server in the IPv4 Internet includes:

translating a received IPv6 message sent by a user-side translator intothe IPv4 message and sending the IPv4 message to the IPv4 server in theIPv4 Internet, when receiving the IPv6 message sent by the user-sidetranslator in the IPv6 network; wherein the received IPv6 message sentby the user-side translator is the IPv6 message having the second-typeprefix which is translated by the user-side translator with the receivedIPv4 message sent by the IPv4 client in the IPv6 network;

determining whether a target port of an IPv4 message fed back by theIPv4 server is within a transport layer port range of the IPv6 server inthe IPv6 network, when receiving the IPv4 message fed back by the IPv4server;

translating the IPv4 message fed back by the IPv4 server into the IPv6message having the second-type prefix and sending the IPv6 message tothe user-side translator so that the user-side translator translates thereceived IPv6 message having the second-type prefix into the IPv4message and sends the IPv4 message to the IPv4 client in the IPv6network, when the target port of the IPv4 message fed back by the IPv4server is not within the transport layer port range of the IPv6 serverin the IPv6 network.

Alternatively, after determining whether the target port of the IPv4message fed back by the IPv4 server is within the transport layer portrange of the IPv6 server in the IPv6 network, the method furtherincludes:

translating the IPv4 message fed back by the IPv4 server into the IPv6message having the first-type prefix and sending the IPv6 message to theIPv6 server, when the target port of the IPv4 message fed back by theIPv4 server is within the transport layer port range of the IPv6 serverin the IPv6 network;

translating the IPv6 message fed back by the IPv6 server into the IPv4message and sending the IPv4 message to the client in the IPv4 Internet,when receiving the IPv6 message fed back by the IPv6 server.

In a second aspect, the embodiments of the present application furtherprovide a device for efficiently using IPv4 public address, which isapplied to a core translator deployed between an IPv4 Internet and anIPv6 network, including:

a first mapping module configured to map an IPv4 public address into afirst-type IPv6 address having a first-type prefix according to atransport layer protocol port range used by an IPv6 server in the IPv6network, so that the IPv6 server uses the first-type IPv6 address tocommunicate with a client in the IPv4 Internet;

a second mapping module configured to map the IPv4 public address into asecond-type IPv6 address having a second-type prefix according to atransport layer protocol port range used by an client in the IPv6network, so that the client in the IPv6 network uses the second-typeIPv6 address to communicate with a IPv4 server in the IPv4 Internet.

In a third aspect, the embodiments of the present application furtherprovide an electronic device, including a processor, a memory, a bus andcomputer programs that are stored in the memory and executable by theprocessor;

wherein the processor and the memory communicate with each other throughthe bus;

the processor implements the methods above when executing the computerprograms.

In a fourth aspect, the embodiments of the present application provide anon-transitory computer readable storage medium, in which computerprograms are stored, wherein the methods above are implemented when thecomputer programs are executed by a processor.

It can be known from the technical solutions above that, by mapping theIPv4 public address into the first-type IPv6 address having thefirst-type prefix according to the transport layer protocol port rangeused by the IPv6 server in the IPv6 network so that the IPv6 server usesthe first-type IPv6 address to communicate with a client in an IPv4Internet, and by mapping the IPv4 public address into the second-typeIPv6 address having the second-type prefix according to the transportlayer protocol port range used by the client in the IPv6 network so thatthe client in the IPv6 network uses the second-type IPv6 address tocommunicate with a IPv4 server in the IPv4 Internet, the embodiments ofthe present application are able to allow the IPv6 server and the clientin the IPv6 network to use the same IPv4 public address to providedifferent services, and maximize the use of the scarce IPv4 publicaddress resources.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly describe the embodiments of the presentapplication or the technical solutions in the prior art, the drawings tobe used in describing the embodiments or the prior art will be brieflydescribed below. Obviously, the drawings in the following descriptionare only some embodiments of the present application, for those ofordinary skill in the art; other drawings may also be obtained based onthese drawings without any creative work.

FIG. 1 is a flowchart of the method for efficiently using IPv4 publicaddress according to an embodiment of the present application;

FIG. 2 is a diagram of the network structure implementing the methods ofthe embodiments of the present application;

FIG. 3 is a specific flowchart of step S1 according to an embodiment ofthe application;

FIG. 4 is a specific flowchart of step S2 according to an embodiment ofthe application;

FIG. 5 is a structural diagram of the device for efficiently using IPv4public address according to an embodiment of the present application;

FIG. 6 is a physical structural diagram of the electronic deviceaccording to an embodiment of the present application.

DETAILED DESCRIPTION

The specific implementation manners of the present application will befurther described with reference to the accompanying drawings. Thefollowing embodiments are only used to more clearly illustrate thetechnical solutions of the present application, and cannot be used tolimit the scope of the present application.

FIG. 1 illustrates a flowchart of the method for efficiently using IPv4public address according to an embodiment of the present application.The method of the present embodiment is applied to a core translatordeployed between an IPv4 Internet and an IPv6 network. As shown in FIG.1, the method for efficiently using IPv4 public address of the presentembodiment includes:

S1, mapping an IPv4 public address into a first-type IPv6 address havinga first-type prefix according to a transport layer protocol port rangeused by an IPv6 server in the IPv6 network, so that the IPv6 server usesthe first-type IPv6 address to communicate with a client in the IPv4Internet.

Wherein, the first-type prefix is not overlapped with a second-typeprefix.

S2, mapping the IPv4 public address into a second-type IPv6 addresshaving a second-type prefix according to a transport layer protocol portrange used by an client in the IPv6 network, so that the client in theIPv6 network uses the second-type IPv6 address to communicate with aIPv4 server in the IPv4 Internet.

It can be appreciated that by using the dual-translation technology ofthe reused IPv4 public addresses of the core translator above, the IPv4client used by a user can communicate with the IPv4 Internet through thepure IPv6 network.

In a specific application, the dual-translation technology in thepresent embodiment can use a stateless address mapping plus portadjustment technology.

It can be appreciated that, FIG. 2 is a diagram of the network structureimplementing the method of the present embodiment. A core IPv4/IPv6extended translator (i.e. the core translator of the present embodiment)is deployed between the IPv4 Internet and the IPv6 network; the IPv6network is connected to a IPv6 server group and can provide services tothe clients (used by the users) in the IPv4 Internet through the coretranslator; the IPv6 network is connected to the user-side IPv4/IPv6translator (i.e. the user-side translator in the present embodiment),and is connected to the IPv4/dual-stack client (used by theIPv4/dual-stack user).

By mapping the IPv4 public address into the first-type IPv6 addresshaving the first-type prefix according to the transport layer protocolport range used by the IPv6 server in the IPv6 network so that the IPv6server uses the first-type IPv6 address to communicate with a client inan IPv4 Internet, and by mapping the IPv4 public address into thesecond-type IPv6 address having the second-type prefix according to thetransport layer protocol port range used by the client in the IPv6network so that the client in the IPv6 network uses the second-type IPv6address to communicate with a IPv4 server in the IPv4 Internet, themethod for efficiently using IPv4 public address, which is applied to acore translator deployed between the IPV4Internet and the IPV6 network,of the present embodiment is able to allow the IPv6 server and theclient in the IPv6 network to use (share) the same IPv4 public addressto provide different services, which can complement the needs of networkproviders and information providers for IPv4 public addresses, and moreefficiently maximize the use of the scarce IPv4 public addressresources.

In addition, on the basis of the embodiment above, before step S1 above,the method of the present embodiment may further include:

Configuring translation parameters including the first-type prefix usedby the IPv6 server in the IPv6 network, the second-type prefix used bythe client in the IPv6 network, the transport layer port range of theIPv6 server, the transport layer port range of the client in the IPv6network, an IPv4 public address pool, and an IPv4 private address poolwith a same size of the IPv4 public address pool; wherein the IPv4public address pool and the IPv4 private address pool have a one-to-onemapping relation.

It can be appreciated that the method of the present embodiment furtherneeds to configure 2 IPv6 addresses for each of the IPv6 servers in theIPv6 network, wherein one of the IPv6 addresses mapped according toRFC6052 is calculated with the IPv4 public address pool and thefirst-type prefix, and the other IPv6 address mapped according toRFC6052 is calculated with the IPv4 private address pool and thefirst-type prefix; configure an authoritative domain name server mappingof the IPv6 server in the IPv6 network, and configure a record AAAA anda record A for each of the IPv6 servers, wherein the record AAAA is theIPv6 address mapped according to RFC6052 and calculated with the IPv4public address pool and the first-type prefix, which is configured bythe IPv6 serve, and the record A is the IPv4 public addresscorresponding to the IPv6 server; and configure parameters fortranslation for the user-side translator, including the second-typeprefix and NAT (network address translation) function.

In addition, on the basis of the embodiment above, as shown in FIG. 3,step S1 above of the present embodiment may include steps S11-S13:

S11, determining whether a target port of an IPv4 message sent by theclient in the IPv4 Internet is within the transport layer port rangeused by the IPv6 server in the IPv6 network, when receiving the IPv4message sent by the client in the IPv4 Internet.

S12, translating the IPv4 message sent by the client in the IPv4Internet into an IPv6 message having the first-type prefix and sendingthe IPv6 message to the IPv6 server, when the target port of the IPv4message sent by the client in the IPv4 Internet is within the transportlayer port range used by the IPv6 server in the IPv6 network.

In a specific application, the IPv4 message sent by the client in theIPv4 Internet may be translated into the IPv6 message having thefirst-type prefix according to RFC6052 and RFC7915.

S13, translating the IPv6 message fed back by the IPv6 server into theIPv4 message and sending the IPv4 message to the client in the IPv4Internet, when receiving the IPv6 message fed back by the IPv6 server.

In a specific application, the IPv6 message fed back by the IPv6 servermay be translated into the IPv4 message according to RFC6052 andRFC7915.

Wherein the IPv4 message sent by the client in the IPv4 Internet is sentbased on the record A which is obtained by the client in the IPv4Internet querying DNS through a domain name server.

Therefore, the present embodiment solves the problem that the IPv6server in the IPv6 network uses the IPv4 public address, which allowsthe IPv6 server to use the first-type IPv6 address, and the IPv6 serverand client in the IPv6 network can share the same IPv4 public address toprovide different services, which can complement the needs of networkproviders and information providers for IPv4 public addresses, and moreefficiently maximize the use of the scarce IPv4 public addressresources.

In addition, on the basis of the embodiment above, as shown in FIG. 4,step S2 above of the present embodiment may include steps S21-S23:

S21, translating a received IPv6 message sent by a user-side translatorinto the IPv4 message and sending the IPv4 message to the IPv4 server inthe IPv4 Internet, when receiving the IPv6 message sent by the user-sidetranslator in the IPv6 network; wherein the received IPv6 message sentby the user-side translator is the IPv6 message having the second-typeprefix which is translated by the user-side translator with the receivedIPv4 message sent by the IPv4 client in the IPv6 network.

It is to be appreciated that, the received IPv4 message sent by the IPv4client in the IPv6 network of the user-side translator is sent based onthe record A which is obtained by the IPv4 client in the IPv6 networkquerying DNS through the domain name server, wherein the domain nameserver directly returns to the record A when it is not the IPv6 serverin the IPv6 network on the side that provides services, and the domainname server returns to IPv4 private address record A obtained accordingto the mapping principle when it is the IPv6 server in the IPv6 networkon the side that provides services.

In a specific application, the IPv6 message sent by the user-sidetranslator may be translated into the IPv4 message according to RFC6052and RFC7915 in this step.

It is to be appreciated that the user-side translator may translate thereceived IPv4 message into the IPv6 message having the second-typeprefix according to NAT rule on the basis of RFC6052 and RFC7915.

S22, determining whether a target port of an IPv4 message fed back bythe IPv4 server is within a transport layer port range of the IPv6server in the IPv6 network, when receiving the IPv4 message fed back bythe IPv4 server.

S23, translating the IPv4 message fed back by the IPv4 server into theIPv6 message having the second-type prefix and sending the IPv6 messageto the user-side translator so that the user-side translator translatesthe received IPv6 message having the second-type prefix into the IPv4message and sends the IPv4 message to the IPv4 client in the IPv6network, when the IPv4 message fed back by the IPv4 server is not withinthe transport layer port range of the IPv6 server in the IPv6 network.

In a specific application, the IPv4 message fed back by the IPv4 servermay be translated into the IPv6 message having the second-type prefixaccording to RFC6052 and RFC7915.

It is to be appreciated that, the user-side translator may translate thereceived IPv6 message having the second-type prefix into the IPv4message according to RFC6052, RFC7915 and NAT rule.

It is to be appreciated that the IPv4 message fed back by the IPv4server is translated into the IPv6 message having the first-type prefixwhich is sent to the IPv6 server, when the IPv4 message fed back by theIPv4 server is within the transport layer port range of the IPv6 serverin the IPv6 network; and the IPv6 message fed back by the IPv6 server istranslated into the IPv4 message which is sent to the client in the IPv4Internet when the IPv6 message fed back by the IPv6 server is received.

Specifically, the IPv4 message fed back by the IPv4 server may betranslated into the IPv6 message having the first-type prefix accordingto RFC6052 and RFC7915, and the IPv6 message fed back by the IPv6 servermay be translated into the IPv4 message according to RFC6052 andRFC7915.

Therefore, the present embodiment allows the client in the IPv6 networkto use the second-type IPv6 address, and the IPv6 server and client inthe IPv6 network can share the same IPv4 public address to providedifferent services, which can complement the needs of network providersand information providers for IPv4 public addresses, and moreefficiently maximize the use of the scarce IPv4 public addressresources.

The method of the embodiments is further described hereinafter with aspecific example.

For example, the first-type prefix of a network is 2001:da8::/32, thesecond-type prefix is 2001: da9::/32, the transport layer port for theIPv6 server in the IPv6 network is 0-1023 and the transport layer portfor the client in the IPv6 network is 1024-65535. The IPv4 publicaddress pool is 1.1.1.0/24, the IPv4 private address pool is10.0.0.0/24, and the mapping relation is that the last 8 bits are equal.A service port of the transport layer of a WEB server in the hometerminal (i.e. the IPv6 network) is 80, the IPv4 public address is1.1.1.10, the IPv4 private address is 10.0.0.10, and two configured IPv6addresses are 2001:da8:0101:010a::, 2001:da8:0a00:000a::. Thecorresponding record AAAA of the authoritative domain name server is2001:da8:0101:010a::, the record A is 1.1.1.10.

When a client 2.0.0.1 in the IPv4 Internet initiates access to the IPv6server above, the record A queried is 1.1.1.10, and the transmittedheader information of the packet is (X is the port number generatedrandomly):

TCP, 2.0.0.1#X, 1.1.1.10#80

The core translator detects that the target port number thereof issmaller than 1023 and translates the address with the first-type prefix2001:da8::/32 according to RFC6052, and the transmitted headerinformation of the packet is:

TCP, [2001:da8:0200:0001::]#X, [2001:da8:0101:010a::]#80

The header information of the packet returned by the IPv6 server is:

TCP, [2001:da8:0101:010a::]#80, [2001:da8:0200:0001::]#X

The transmitted header information of the packet after the coretranslator is:

TCP, 1.1.1.10#80, 2.0.0.1#X

The process is repeated until the communication is finished.

When an IPv4 client 192.168.0.3 in the IPv6 network initiates access toa WEB server of the IPv4 Internet, the record A queried by the domainname resolver is 3.0.0.6. Since it is not within the range of the IPv4public address shared on the side, it is returned and the transmittedheader information of the packet is (Y is the port number generatedrandomly):

TCP, 192.168.0.3% Y, 3.0.0.6#80

The transmitted header information of the packet after NAT is (Z is theport number after NAT translation):

TCP, 1.1.1.10% Z (Z>1024), 3.0.0.6#80

The address is translated with the second-type prefix 2001:da9::/32according to RFC6052 after the user-side translator, the transmittedheader information of the packet is:

TCP, [2001:da9:0101:010a::]#Z, [2001:da9:0300:0006::]#80

The address is translated according to RFC6052 after the coretranslator, the transmitted header information of the packet is:

TCP, 1.1.1.10% Z, 3.0.0.6#80

The header information of the packet returned by the IPv4 server in theIPv4 Internet is:

TCP, 3.0.0.6#80, 1.1.1.10% Z

The core translator detects that the target port number thereof isgreater than 1023 and translates the address with the second-type prefix2001:da9::/32 according to RFC6052, and the transmitted headerinformation of the packet is:

TCP, [2001:da9:0300:0006:]#80, [2001:da9:0101:010a::]#Z

The address is translated according to RFC6052 after the user-sidetranslator, the transmitted header information of the packet is:

TCP, 3.0.0.6#80, 1.1.1.10% Z

The transmitted header information of the packet after NAT is:

TCP, 3.0.0.6#80, 192.168.0.3% Y

The process is repeated until the communication is finished.

When an IPv4 client 192.168.0.3 in the IPv6 network initiates access toa WEB server of the IPv6 network, the record A queried by the domainname resolver is 1.1.1.9, it is translated into the correspondingprivate address 10.0.0.9 as the record A to be provided to the IPv4client, and the transmitted header information of the packet is (U isthe port number generated randomly):

TCP, 192.168.0.3% U, 10.0.0.9#80

The transmitted header information of the packet after NAT is (V is theport number after NAT translation):

TCP, 1.1.1.10% V (V>1024), 10.0.0.9#80

The address is translated with the IPv6 prefix 2001:da9::/32 of theclient according to RFC6052 after the user-side translator, thetransmitted header information of the packet is:

TCP, [2001:da9:0101:010a::]#V, [2001:da9:0a00:0009:]#80

The address is translated according to RFC6052 after the coretranslator, the transmitted header information of the packet is:

TCP, 1.1.1.10% V, 10.0.0.9#80

The header information of the packet returned by the IPv4 server is:

TCP, 10.0.0.9#80, 1.1.1.10% V

The address is translated with the second-type prefix 2001:da9::/32according to RFC6052 after the core translator, the transmitted headerinformation of the packet is:

TCP, [2001:da9:0a00:0009:]#80, [2001:da9:0101:010a::]#V

The address is translated according to RFC6052 after the user-sidetranslator, the transmitted header information of the packet is:

TCP, 10.0.0.9#80, 1.1.1.10% V

The transmitted header information of the packet after NAT is:

TCP, 10.0.0.9#80, 192.168.0.3% U

The process is repeated until the communication is finished.

The method for efficiently using IPv4 public address allows the IPv6server and the client to use (share) the same IPv4 public address toprovide different services, which can complement the needs of networkproviders and information providers for IPv4 public addresses, and moreefficiently maximize the use of the scarce IPv4 public addressresources.

FIG. 5 illustrates a structural diagram of the device for efficientlyusing IPv4 public address according to an embodiment of the presentapplication. The device of the present embodiment is applied to a coretranslator deployed between an IPv4 Internet and an IPv6 network. Asshown in FIG. 5, the device for efficiently using IPv4 public address ofthe present embodiment includes a first mapping module 51 and a secondmapping module 52, wherein

the first mapping module 51 is configured to map an IPv4 public addressinto a first-type IPv6 address having a first-type prefix according to atransport layer protocol port range used by an IPv6 server in the IPv6network, so that the IPv6 server uses the first-type IPv6 address tocommunicate with a client in the IPv4 Internet;

the second mapping module 52 is configured to map the IPv4 publicaddress into a second-type IPv6 address having a second-type prefixaccording to a transport layer protocol port range used by an client inthe IPv6 network, so that the client in the IPv6 network uses thesecond-type IPv6 address to communicate with a IPv4 server in the IPv4Internet.

Specifically, the first mapping module 51 maps the IPv4 public addressinto the first-type IPv6 address having the first-type prefix accordingto the transport layer protocol port range used by the IPv6 server inthe IPv6 network, so that the IPv6 server uses the first-type IPv6address to communicate with the client in the IPv4 Internet; the secondmapping module 52 maps the IPv4 public address into the second-type IPv6address having the second-type prefix according to the transport layerprotocol port range used by the client in the IPv6 network, so that theclient in the IPv6 network uses the second-type IPv6 address tocommunicate with the IPv4 server in the IPv4 Internet.

Wherein, the first-type prefix is not overlapped with the second-typeprefix.

It can be appreciated that by using the dual-translation technology ofthe reused IPv4 public addresses of the core translator above, the IPv4client used by a user can communicate with the IPv4 Internet through thepure IPv6 network.

In a specific application, the dual-translation technology in thepresent embodiment can use a stateless address mapping plus portadjustment technology.

The device for efficiently using IPv4 public address is applied to thecore translator deployed between the IPv4 Internet and IPv6 network, andcan allow the IPv6 server and the client to use (share) the same IPv4public address to provide different services, which can complement theneeds of network providers and information providers for IPv4 publicaddresses, and more efficiently maximize the use of the scarce IPv4public address resources.

In addition, on the basis of the embodiment above, the device of thepresent embodiment may further include the following modules not shownin the drawings:

a configuring module configured to configure translation parametersincluding the first-type prefix used by the IPv6 server in the IPv6network, the second-type prefix used by the client in the IPv6 network,a transport layer port range of the IPv6 server, a transport layer portrange of the client in the IPv6 network, an IPv4 public address pool,and an IPv4 private address pool with a same size of the IPv4 publicaddress pool; wherein the IPv4 public address pool and the IPv4 privateaddress pool have a one-to-one mapping relation.

It can be appreciated that it further needs to configure 2 IPv6addresses for each of the IPv6 servers in the IPv6 network in thepresent embodiment, wherein one of the IPv6 addresses mapped accordingto RFC6052 is calculated with the IPv4 public address pool and thefirst-type prefix, and the other IPv6 address mapped according toRFC6052 is calculated with the IPv4 private address pool and thefirst-type prefix; configure an authoritative domain name server mappingof the IPv6 server in the IPv6 network, and configure the record AAAAand the record A for each of the IPv6 servers, wherein the record AAAAis the IPv6 address mapped according to RFC6052, calculated with theIPv4 public address pool and the first-type prefix and configured by theIPv6 serve, and the record A is the IPv4 public address corresponding tothe IPv6 server; and configure parameters for translation for theuser-side translator, including the second-type prefix and NAT (networkaddress translation) function.

In addition, on the basis of the embodiments above, the first mappingmodule 51 may be specifically configured to determine whether a targetport of an IPv4 message sent by the client in the IPv4 Internet iswithin the transport layer port range of the IPv6 server in the IPv6network, when receiving the IPv4 message sent by the client in the IPv4Internet;

translate the IPv4 message sent by the client in the IPv4 Internet intoan IPv6 message having the first-type prefix and send the IPv6 messageto the IPv6 server, when the target port of the IPv4 message sent by theclient in the IPv4 Internet is within the transport layer port range ofthe IPv6 server in the IPv6 network;

translate the IPv6 message fed back by the IPv6 server into the IPv4message and send the IPv4 message to the client in the IPv4 Internet,when receiving the IPv6 message fed back by the IPv6 server.

Wherein the IPv4 message sent by the client in the IPv4 Internet is sentbased on the record A which is obtained by the client in the IPv4Internet querying DNS through a domain name server.

Therefore, the present embodiment solves the problem that the IPv6server in the IPv6 network uses the IPv4 public address, allows the IPv6server to use the first-type IPv6 address, and the IPv6 server andclient in the IPv6 network can share the same IPv4 public address toprovide different services, which can complement the needs of networkproviders and information providers for IPv4 public addresses, and moreefficiently maximize the use of the scarce IPv4 public addressresources.

In addition, on the basis of the embodiments above, the first mappingmodule 52 may be specifically configured to

translate a received IPv6 message sent by a user-side translator intothe IPv4 message and send the IPv4 message to the IPv4 server in theIPv4 Internet, when receiving the IPv6 message sent by the user-sidetranslator in the IPv6 network; wherein the received IPv6 message sentby the user-side translator is the IPv6 message having the second-typeprefix which is translated by the user-side translator with the receivedIPv4 message sent by the IPv4 client in the IPv6 network;

determine whether a target port of an IPv4 message fed back by the IPv4server is within a transport layer port range of the IPv6 server in theIPv6 network, when receiving the IPv4 message fed back by the IPv4server;

translate the IPv4 message fed back by the IPv4 server into the IPv6message having the second-type prefix and send the IPv6 message to theuser-side translator so that the user-side translator translates thereceived IPv6 message having the second-type prefix into the IPv4message and send the IPv4 message to the IPv4 client in the IPv6network, when the target port of the IPv4 message fed back by the IPv4server is not within the transport layer port range of the IPv6 serverin the IPv6 network.

Wherein the received IPv4 message sent by the IPv4 client in the IPv6network of the user-side translator is sent based on the record A whichis obtained by the IPv4 client in the IPv6 network querying DNS throughthe domain name server, wherein the domain name server directly returnsto the record A when it is not the IPv6 server in the IPv6 network onthe side that provides services, and the domain name server returns toIPv4 private address record A obtained according to the mappingprinciple when it is the IPv6 server in the IPv6 network on the sidethat provides services.

In addition, the first mapping module 52 may be further specificallyconfigured to

translate the IPv4 message fed back by the IPv4 server into the IPv6message having the first-type prefix which is sent to the IPv6 server,when the IPv4 message fed back by the IPv4 server is within thetransport layer port range of the IPv6 server in the IPv6 network; andtranslate the IPv6 message fed back by the IPv6 server into the IPv4message which is sent to the client in the IPv4 Internet when receivingthe IPv6 message fed back by the IPv6 server.

Therefore, the present embodiment allows the client in the IPv6 networkto use the first-type IPv6 address, and the IPv6 server and client inthe IPv6 network can share the same IPv4 public address to providedifferent services, which can complement the needs of network providersand information providers for IPv4 public addresses, and moreefficiently maximize the use of the scarce IPv4 public addressresources.

The device for efficiently using IPv4 public address of the presentembodiment can execute the technical solutions of the method embodimentsabove. The implementation principle and technical effects of them aresimilar, and will not be repeated herein.

FIG. 6 illustrates a physical structure of an electronic device providedby an embodiment of the present application. As shown in FIG. 6, theelectronic device may include: a processor 61, a memory 62, a bus 63 andcomputer programs that are stored in the memory 62 and executable by theprocessor 61;

wherein the processor 61 and the memory 62 communicate with each otherthrough the bus 63;

the processor 61 implements the methods of the method embodiments abovewhen executes the computer programs. The methods, for example, mayinclude mapping the IPv4 public address into the first-type IPv6 addresshaving the first-type prefix according to the transport layer protocolport range used by the IPv6 server in the IPv6 network, so that the IPv6server uses the first-type IPv6 address to communicate with the clientin the IPv4 Internet; mapping the IPv4 public address into thesecond-type IPv6 address having the second-type prefix according to thetransport layer protocol port range used by the client in the IPv6network, so that the client in the IPv6 network uses the second-typeIPv6 address to communicate with the IPv4 server in the IPv4 Internet.

The embodiments of the present application provide a non-transitorycomputer readable storage medium, in which computer programs are stored,wherein the methods of the method embodiments above are implemented whenthe computer programs are executed by a processor. The methods, forexample, may include mapping the IPv4 public address into the first-typeIPv6 address having the first-type prefix according to the transportlayer protocol port range used by the IPv6 server in the IPv6 network,so that the IPv6 server uses the first-type IPv6 address to communicatewith the client in the IPv4 Internet; mapping the IPv4 public addressinto the second-type IPv6 address having the second-type prefixaccording to the transport layer protocol port range used by the clientin the IPv6 network, so that the client in the IPv6 network uses thesecond-type IPv6 address to communicate with the IPv4 server in the IPv4Internet.

The person skilled in the art should appreciate that the embodiments ofthe present application can be provided as a method, a device, or acomputer program product. Therefore, the present application can beimplemented in the form of an entire-hardware embodiment, anentire-software embodiment, or an embodiment in combination of softwareand hardware. Moreover, the application can be implemented in the formof a computer program product that can be implemented in one or morecomputer applicable storage mediums (including but not limited to diskstorage, CD-ROM, optical storage, etc.) including computer applicableprogram codes.

The present application is described with reference to the flowchartsand/or block diagrams of the methods, devices and computer programproducts according to the embodiments of the present application. It isto be appreciated that the flowchart and/or each process in the blockdiagram and/or blocks, and the combinations of the flowchart and/or theprocess in the block diagram and/or blocks can be implemented withcomputer program instructions. These computer program instructions canbe provided to a processor of a general-purpose computer, aspecial-purpose computer, an embedded computer, or other programmabledata processing device to produce a machine, so that the instructionsexecuted by the processor of the computer or other programmable dataprocessing device generate a device/system for achieving the functionsdesignated in one or more processes in the flowchart(s) and/or one ormore blocks in the block diagram(s).

These computer program instructions can also be stored in a computerreadable memory that can guide a computer or other programmable dataprocessing device to operate in a particular manner, so that theinstructions stored in the computer readable memory produce amanufacture including an instruction device implementing the functionsdesignated in one or more processes in the flowchart(s) and/or one ormore blocks in the block diagram(s).

These computer program instructions can also be loaded onto a computeror other programmable data processing devices, so that a series ofoperational steps is performed on the computer or other programmabledevices to generate the processing implemented by computer, so that theinstructions executed on the computer or other programmable devicesprovide steps for achieving the functions designated in one or moreprocesses in the flowchart(s) and/or one or more blocks in the blockdiagram(s).

It is to be noted that, in this context, relational terms such as thefirst type and the second type are used merely to distinguish one entityor operation from another entity or operation, and do not necessarilyrequire or imply that such actual relationship or order exists betweenthese entities or operations. Furthermore, the terms “include”,“comprise” or any other variations thereof are intended to encompass anon-exclusive inclusion, such that a process, method, article, or deviceincluding a plurality of elements includes not only those elements butalso other elements that are not explicitly listed, or elements that areinherent to such process, method, item, or device. An element that isdefined by term “including/comprising a . . . ” does not exclude thepresence of additional equivalent elements in the process, method, item,or device that includes the element. The orientation or positionrelations indicated by the terms “upper”, “lower”, etc. are based on theorientation or position relations shown in the drawings, which aremerely for the convenience of describing the present application andsimplifying the description, and do not indicate or imply that thedevice or component referred to must have the specific orientation, beconstructed and operated in the specific orientation. Therefore itcannot be construed as limiting the present application. Unlessspecifically defined or limited, the terms “mount”, “connect to”, and“connect with” should be understood in a broad sense, for example, theymay be fixed connections or may be removable connections, or integratedconnections; may be mechanical connections or electrical connections;they may also be direct connections or indirect connections throughintermediate medium, or may be internal communication of two components.For a person of ordinary skill in the art, the specific meanings of theterms above in the present application can be understood according tospecific situations.

In the description of the present application, numerous specific detailsare set forth. However, it is to be appreciated that the embodiments ofthe present application may be practiced without these specific details.In some instances, well-known methods, structures and techniques are notshown in detail so as not to obscure the understanding of thedescription. Similarly, it is to be appreciated that, in order tosimplify the disclosure of the present application and facilitate theunderstanding of one or more of the various invention aspects, variousfeatures of the application are sometimes grouped together into a singleembodiment, diagram or the description thereof in the description of theexemplary embodiments of the present application. However, the disclosedmethods should not be construed as reflecting the intention that thepresent application sought to be protected requires more features thanthose specifically recited in each of the claims. Or rather, asreflected in the claims, the inventive aspects lie in being less thanall features of the single embodiment disclosed above. Therefore, theclaims following the embodiments are hereby explicitly incorporated intothe embodiments, and each of the claims is a separate embodiment of thepresent application. It is to be noted that the embodiments of thepresent application and the features in the embodiments may be combinedwith each other without conflict. The present application is not limitedto any single aspect, or to any single embodiment, or to any combinationand/or substitution of these aspects and/or embodiments. Moreover, eachaspect and/or embodiment of the present application may be used alone orin combination with one or more other aspects and/or other embodimentsthereof.

Finally, it is to be noted that each embodiment above is only used toillustrate rather than limit the technical solutions of the presentapplication; although the present application has been described indetail with reference to the foregoing embodiments, those of ordinaryskill in the art should appreciate that they can still modify thetechnical solutions described in the foregoing embodiments, orequivalently replace some or all of the technical features therein; andthese modifications or replacements do not separate the essence of thecorresponding technical solutions from the spirit and scope of thetechnical solutions of each of the embodiments of the presentapplication, all of which should fall within the scope of the claims anddescription of the present application.

1. A method for efficiently using IPv4 public address, which is appliedto a core translator deployed between an IPv4 Internet and an IPv6network, comprising: mapping an IPv4 public address into a first-typeIPv6 address having a first-type prefix according to a transport layerprotocol port range used by an IPv6 server in the IPv6 network, so thatthe IPv6 server uses the first-type IPv6 address to communicate with aclient in the IPv4 Internet; and mapping the IPv4 public address into asecond-type IPv6 address having a second-type prefix according to atransport layer protocol port range used by an client in the IPv6network, so that the client in the IPv6 network uses the second-typeIPv6 address to communicate with a IPv4 server in the IPv4 Internet. 2.The method of claim 1, wherein before mapping the IPv4 public addressinto the first-type IPv6 address having the first-type prefix accordingto the transport layer protocol port range used by the IPv6 server inthe IPv6 network, so that the IPv6 server uses the first-type IPv6address to communicate with the client in the IPv4 Internet, the methodfurther comprises: configuring translation parameters comprising thefirst-type prefix used by the IPv6 server in the IPv6 network, thesecond-type prefix used by the client in the IPv6 network, a transportlayer port range of the IPv6 server, a transport layer port range of theclient in the IPv6 network, an IPv4 public address pool, and an IPv4private address pool with a same size of the IPv4 public address pool;wherein the IPv4 public address pool and the IPv4 private address poolhave a one-to-one mapping relation.
 3. The method of claim 1, whereinthe first-type prefix and the second-type prefix are not overlapped. 4.The method of claim 1, wherein mapping the IPv4 public address into thefirst-type IPv6 address having the first-type prefix according to thetransport layer protocol port range used by the IPv6 server in the IPv6network, so that the IPv6 server uses the first-type IPv6 address tocommunicate with the client in the IPv4 Internet comprises: determiningwhether a target port of an IPv4 message sent by the client in the IPv4Internet is within the transport layer port range of the IPv6 server inthe IPv6 network, when receiving the IPv4 message sent by the client inthe IPv4 Internet; translating the IPv4 message sent by the client inthe IPv4 Internet into an IPv6 message having the first-type prefix andsending the IPv6 message to the IPv6 server, when the target port of theIPv4 message sent by the client in the IPv4 Internet is within thetransport layer port range of the IPv6 server in the IPv6 network;translating the IPv6 message fed back by the IPv6 server into the IPv4message and sending the IPv4 message to the client in the IPv4 Internet,when receiving the IPv6 message fed back by the IPv6 server.
 5. Themethod of claim 4, wherein the IPv4 message sent by the client in theIPv4 Internet is sent based on a record A which is obtained by theclient in the IPv4 Internet querying DNS through a domain name server.6. The method of claim 1, wherein mapping the IPv4 public address intothe second-type IPv6 address having the second-type prefix according tothe transport layer protocol port range used by the client in the IPv6network, so that the client in the IPv6 network uses the second-typeIPv6 address to communicate with the IPv4 server in the IPv4 Internetcomprises: translating a received IPv6 message sent by a user-sidetranslator into the IPv4 message and sending the IPv4 message to theIPv4 server in the IPv4 Internet, when receiving the IPv6 message sentby the user-side translator in the IPv6 network; wherein the receivedIPv6 message sent by the user-side translator is the IPv6 message havingthe second-type prefix which is translated by the user-side translatorwith the received IPv4 message sent by the IPv4 client in the IPv6network; determining whether a target port of an IPv4 message fed backby the IPv4 server is within a transport layer port range of the IPv6server in the IPv6 network, when receiving the IPv4 message fed back bythe IPv4 server; translating the IPv4 message fed back by the IPv4server into the IPv6 message having the second-type prefix and sendingthe IPv6 message to the user-side translator so that the user-sidetranslator translates the received IPv6 message having the second-typeprefix into the IPv4 message and sends the IPv4 message to the IPv4client in the IPv6 network, when the target port of the IPv4 message fedback by the IPv4 server is not within the transport layer port range ofthe IPv6 server in the IPv6 network.
 7. The method of claim 6, whereinafter determining whether the target port of the IPv4 message fed backby the IPv4 server is within the transport layer port range of the IPv6server in the IPv6 network, the method further comprises: translatingthe IPv4 message fed back by the IPv4 server into the IPv6 messagehaving the first-type prefix and sending the IPv6 message to the IPv6server, when the target port of the IPv4 message fed back by the IPv4server is within the transport layer port range of the IPv6 server inthe IPv6 network; translating the IPv6 message fed back by the IPv6server into the IPv4 message and sending the IPv4 message to the clientin the IPv4 Internet, when receiving the IPv6 message fed back by theIPv6 server.
 8. A device for efficiently using IPv4 public address,which is applied to a core translator deployed between an IPv4 Internetand an IPv6 network, comprising: a first mapping module configured tomap an IPv4 public address into a first-type IPv6 address having afirst-type prefix according to a transport layer protocol port rangeused by an IPv6 server in the IPv6 network, so that the IPv6 server usesthe first-type IPv6 address to communicate with a client in the IPv4Internet; a second mapping module configured to map the IPv4 publicaddress into a second-type IPv6 address having a second-type prefixaccording to a transport layer protocol port range used by an client inthe IPv6 network, so that the client in the IPv6 network uses thesecond-type IPv6 address to communicate with a IPv4 server in the IPv4Internet.
 9. A non-transitory computer readable storage medium, in whichcomputer programs are stored, wherein the method of claim 1 isimplemented when the computer programs are executed by a processor.